CN102735385B - Method for detecting impact energy of hydraulic breaking hammer - Google Patents
Method for detecting impact energy of hydraulic breaking hammer Download PDFInfo
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- CN102735385B CN102735385B CN201110084152.0A CN201110084152A CN102735385B CN 102735385 B CN102735385 B CN 102735385B CN 201110084152 A CN201110084152 A CN 201110084152A CN 102735385 B CN102735385 B CN 102735385B
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- hydraulic hammer
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Abstract
The invention relates to a method for detecting impact energy of a hydraulic breaking hammer. The method comprises the following steps that: 1) a pressure sensor collects pressure signals and sends the pressure signals to a data acquisition card; 2) the data acquisition card converts the pressure signals and sends the converted signals to a computer; 3) the computer stores the pressure signals in memory and displays the pressure signals on a displayer in the form of a curve; 4) the computer judges the type of the hydraulic hammer and calculates respectively to obtain acceleration curves of a piston; 5) the computer carries out numerical integration processing on the acceleration curves of the piston by using the Simpson's rule to obtain a maximum speed and further to obtain the impact energy. Compared with the prior art, the method of the invention has the advantages of simple detection method, safe and convenient operation, high measurement accuracy, and the like.
Description
Technical field
The present invention relates to a kind of detection method of impact energy, especially relate to a kind of detection method of hydraulic breaking hammer impact energy.
Background technology
Impact energy reflects the breaking capacity of hydraulic hammer, and frequency of impact reflects the broken speed of hydraulic hammer, and this is two very important parameters.In the sample or technological document of many manufacturers, often only provide frequency of impact, do not mark impact energy.For frequency of impact, the detection of impact energy is a very difficult expensive thing that wastes time and energy.Because do not have unified detection method and standard, the accuracy of measured result, repeatability, comparability are all very poor, easily controversial, the reason of many manufacturers do not provide impact energy that Here it is.
At present, conventional knocker impact energy performance test methods has end speed method, indicator diagram method, stress wave, mechanical measurement method, nitrogen chamber tonometry.
Example, CN 1387030A discloses a kind of nitrogen chamber pressure of measuring to calculate the method for the kinetic energy of piston, and this measuring method is simple and easy to do, but for not having the all-hydraulic acting hydraulic hammer of nitrogen chamber, then cannot use.It is the change according to nitrogen chamber volume simultaneously, solve the displacement of piston movement, extrapolate the maximal rate of piston movement, finally draw kinetic energy, but have ignored the weight of chamber active area and piston itself before and after piston, degree of accuracy of obtaining a result does not have the present invention accurate.
Summary of the invention
Object of the present invention is exactly provide a kind of method of testing simple to overcome defect that above-mentioned prior art exists, handling safety, convenience, the detection method of the hydraulic breaking hammer impact energy that measurement accuracy rate is high.
Object of the present invention can be achieved through the following technical solutions: a kind of detection method of hydraulic breaking hammer impact energy, and it is characterized in that, the method comprises the following steps: 1) pressure transducer gathers pressure signal, and sends to data collecting card; 2) data collecting card is changed pressure signal, and the signal after conversion is sent to computing machine; 3) pressure signal stores in memory by computing machine, and is shown over the display in graph form by pressure signal; 4) computing machine judges hydraulic hammer classification, if be judged as nitrogen explosion type hydraulic hammer, carry out step 5), if be judged as dynamic hydraulic combined formula hydraulic hammer, carry out step 6), if be judged as full-liquid type hydraulic hammer, carry out step 7); 5) computing machine is according to the physical parameter of the nitrogen pressure curve of nitrogen explosion type hydraulic hammer, epicoele oil pressure curve and nitrogen explosion type hydraulic hammer, calculates the accelerating curve of the piston of nitrogen explosion type hydraulic hammer, and carry out step 8); 6) computing machine is according to the physical parameter of the nitrogen pressure curve of dynamic hydraulic combined formula hydraulic hammer, epicoele oil pressure curve and dynamic hydraulic combined formula hydraulic hammer, calculates the accelerating curve of the piston of dynamic hydraulic combined formula hydraulic hammer, and carry out step 8); 7) the epicoele oil pressure curve of computing machine according to full-liquid type hydraulic hammer and the physical parameter of cavity of resorption oil pressure curve and full-liquid type hydraulic hammer, calculate the accelerating curve of the piston of full-liquid type hydraulic hammer, and carry out step 8); 8) utilize Simpson's rule to carry out numerical integration process to the accelerating curve of piston, draw maximal rate, and draw impact energy further.
Described step 1) in pressure transducer be arranged on valve place and the epicoele fluid mouth of pipe place of the nitrogen chamber of nitrogen explosion type hydraulic hammer, or be arranged on the valve place of nitrogen chamber and the epicoele fluid mouth of pipe place of dynamic hydraulic combined formula hydraulic hammer, or be arranged on epicoele fluid mouth of pipe place and the cavity of resorption fluid mouth of pipe place of full-liquid type hydraulic hammer.
Described step 5) comprise the nitrogen pressure curve crest of computing machine intercepting nitrogen explosion type hydraulic hammer to the data in decrease amount section, intercept the data of the epicoele oil pressure curve in same time section simultaneously.
Described step 6) comprise the nitrogen pressure curve crest of computing machine intercepting dynamic hydraulic combined formula hydraulic hammer to the data in decrease amount section, intercept the data of the epicoele oil pressure curve in same time section simultaneously.
Described step 7) comprise computing machine the value of any point on epicoele oil pressure curve and the average centered by this point in two seconds are compared, and intercept oil pressure value from being greater than average to the curve be less than average.
Described step 7) also comprise computing machine the value of any point on cavity of resorption oil pressure curve and the average centered by this point in two seconds are compared, and intercept oil pressure value from being greater than average to the curve be less than average.
Compared with prior art, the present invention accurately can detect the impact energy of quartering hammer, and method of testing is simple, handling safety, convenience.Not only can be used for the impact energy of laboratory to quartering hammer to test, also can make factory inspection for the production of the breaking hammer performance of producer to various operating mode easily.
Accompanying drawing explanation
Fig. 1 is process flow diagram of the present invention;
Fig. 2 is the syndeton schematic diagram of apparatus of the present invention when application state;
Fig. 3 is the syndeton schematic diagram adopting the present invention to test dynamic hydraulic combined formula hydraulic hammer;
Fig. 4 is the syndeton schematic diagram adopting the present invention to test nitrogen explosion type hydraulic hammer;
Fig. 5 is the syndeton schematic diagram adopting the present invention to test dynamic hydraulic combined formula hydraulic hammer.
Embodiment
Below in conjunction with the drawings and specific embodiments, the present invention is described in detail.
Embodiment 1
As shown in Figure 1, a kind of detection method of hydraulic breaking hammer impact energy, the method comprises the following steps:
Step 1) pressure transducer collection pressure signal, and send to data collecting card.Pressure transducer is according to the difference of the device that will detect, during use, its installation site is also different, pressure transducer can be arranged on valve place and the epicoele fluid mouth of pipe place of the nitrogen chamber of nitrogen explosion type hydraulic hammer, also can be arranged on valve place and the epicoele fluid mouth of pipe place of the nitrogen chamber of dynamic hydraulic combined formula hydraulic hammer, epicoele fluid mouth of pipe place and the cavity of resorption fluid mouth of pipe place of full-liquid type hydraulic hammer can also be arranged on.
Step 2) data collecting card changes pressure signal, and the signal after conversion is sent to computing machine;
Step 3) pressure signal stores in memory, and to be shown over the display in graph form by pressure signal by computing machine;
Step 4) computing machine judges hydraulic hammer classification, if be judged as nitrogen explosion type hydraulic hammer, then computing machine is according to the physical parameter of the nitrogen pressure curve of nitrogen explosion type hydraulic hammer, epicoele oil pressure curve and nitrogen explosion type hydraulic hammer, calculate the accelerating curve of the piston of nitrogen explosion type hydraulic hammer, and carry out step 5).When computing machine processes, need the nitrogen pressure curve crest intercepting nitrogen explosion type hydraulic hammer to the data in decrease amount section, intercept the data of the epicoele oil pressure curve in same time section simultaneously.
If be judged as dynamic hydraulic combined formula hydraulic hammer, then computing machine is according to the physical parameter of the nitrogen pressure curve of dynamic hydraulic combined formula hydraulic hammer, epicoele oil pressure curve and dynamic hydraulic combined formula hydraulic hammer, calculate the accelerating curve of the piston of dynamic hydraulic combined formula hydraulic hammer, and carry out step 5).When computing machine processes, need the nitrogen pressure curve crest intercepting dynamic hydraulic combined formula hydraulic hammer to the data in decrease amount section, intercept the data of the epicoele oil pressure curve in same time section simultaneously.
If be judged as full-liquid type hydraulic hammer, then the epicoele oil pressure curve of computing machine according to full-liquid type hydraulic hammer and the physical parameter of cavity of resorption oil pressure curve and full-liquid type hydraulic hammer, calculate the accelerating curve of the piston of full-liquid type hydraulic hammer, and carry out step 5).When computing machine processes, need to compare the value of any point on epicoele oil pressure curve and the average centered by this point in two seconds, and intercept oil pressure value from being greater than average to the curve be less than average.When the cavity of resorption oil pressure of full-liquid type hydraulic hammer also changes, computing machine also needs to compare the value of any point on cavity of resorption oil pressure curve and the average centered by this point in two seconds, and intercepts oil pressure value from being greater than average to the curve be less than average.
Step 5) utilize Simpson's rule to carry out numerical integration process to the accelerating curve of piston, draw maximal rate, and draw impact energy further.
As shown in Figure 2, as follows for implementing the hardware unit that also needs of the inventive method: computing machine 23, data collecting card 22, pressure signal sensor 21.Pressure signal sensor 21 is connected with data collecting card 22, send the pressure sensor signal of collection to data collecting card 22, data collecting card 22 pairs of pressure sensor signals are changed, and send the pressure sensor signal after conversion to computing machine 23, through the process of VC programmed process software, by result display over the display.
As shown in Figure 3, for dynamic hydraulic combined formula hydraulic hammer, piston is in a work period, and piston movement has two kinds of operating modes: backhaul and stroke.
Backhaul: moved by the cross complaint of valve and piston, during backhaul, epicoele 31 leads to oil return, and piston 32 upwards does drawback movement.Piston 32 is when drawback movement, compressed nitrogen, thus the pressure of nitrogen chamber 33 is raised, the volume of nitrogen chamber 33 reduces, piston 32 slows down under the effect of gravity and nitrogen pressure, until speed reduces to zero, now valve 34 completes commutation, and piston upper chamber 31 and oil back chamber are isolated, communicate with cavity of resorption 35, form differential connection, upper and lower cavity pressure is equal, is all hydraulic oil.
Stroke: now due to P1=P2, piston speed is zero, deadweight and nitrogen pressure effect under, stroke of piston start accelerate, piston stroke speed strengthen, nitrogen chamber pressure reduction, finally with maximum velocity shock drill steel, fulfil assignment.
In the process of stroke, nitrogen chamber can regard a nitrogen spring device as, before and after the elastic potential energy of nitrogen spring, piston under the differential energy in chamber and the effect of deadweight, is all converted into kinetic energy, impacts drill steel.Piston stress balance goes out formula and is:
P
3A
3+P
2A
2-P
1A
1+mg=ma
Now, P
2=P
1, ∴ acceleration
P
3------nitrogen chamber pressure (sensor is measured);
A
3------nitrogen chamber active area;
P
2------upper cavity pressure (sensor is measured);
A
2------epicoele active area;
P
1------lower cavity pressure;
A
1------cavity of resorption active area;
M------piston mass;
G------acceleration of gravity.
For dynamic hydraulic combined formula quartering hammer, we need to arrange pressure transducer at the valve place of nitrogen chamber and epicoele fluid mouth of pipe place, data due to pressure transducer measurement had both comprised the data that backhaul also comprises stroke, as long as intercept out nitrogen chamber and epicoele pressure history in stroke movement, in conjunction with other constant A
1, A
2, A
3, m, g, just the form of the acceleration a curve of piston movement can be showed.
Embodiment 2
For nitrogen explosion type hydraulic hammer, as shown in Figure 4, when backhaul starts, piston upper chamber 42 leads to oil return, and cavity of resorption 41 leads to hydraulic oil.The hydraulic oil of cavity of resorption 41 promote piston 44 and piston overpowers is conducted oneself with dignity and nitrogen chamber 43 pressure and on move.Now top land compressed nitrogen, the pressure of nitrogen raises, and piston is slowed down, finally completes backhaul.
Piston starts stroke, and cavity of resorption 41 switches oil circuit by reversal valve 46, and make epicoele 42 lead to hydraulic oil, cavity of resorption 41 leads to oil return.During stroke, piston is moved down for the effect of epicoele oil pressure and nitrogen pressure effect and fast stroke is externally done work, and considers piston gravity, and suffered frictional resistance and return pressure when ignoring piston movement, show that piston stress balance formula is:
P
3A
3+P
2A
2+mg=ma
V ∴ acceleration
For nitrogen explosion type quartering hammer, we need at the valve place of nitrogen chamber and epicoele fluid mouth of pipe place setting pressure sensor 45 respectively, data due to pressure transducer measurement had both comprised the data that backhaul also comprises stroke, as long as intercept out the change curve of nitrogen chamber and epicoele pressure in stroke movement,, in conjunction with other constant A
2, A
3, m, g, just the form of the acceleration a curve of piston movement can be showed.
Embodiment 3
For nitrogen explosion type hydraulic hammer, as shown in Figure 5, most of all-hydraulic quartering hammer, when backhaul starts, piston cavity of resorption 51 leads to hydraulic oil, and epicoele 52 leads to oil return.Affect by cavity of resorption hydraulic oil, when piston 53 moves on to certain position on accelerating, feed back to reversal valve 55, the at this moment upper connection of reversal valve by telltale hole, all logical hydraulic oil of piston upper and lower cavity, defines differential connection.Due to piston upper chamber annulus area A
2be greater than cavity of resorption annulus area A
1, so epicoele oil pressure is greater than cavity of resorption oil pressure, piston is backhaul braking under differential pressure action.Under differential connection, start stroke again simultaneously, get back to original state, start again next backhaul.Consider piston gravity, frictional resistance suffered when ignoring piston movement, show that piston stress balance formula is:
P
2A
2-P
1A
1+mg=ma
∴ acceleration
For full hydraulic quartering hammer, we need at epicoele fluid mouth of pipe place and cavity of resorption fluid mouth of pipe place setting pressure sensor 54 (because the all-hydraulic quartering hammer cavity of resorption of the manufacturer production had becomes hydraulic pressure), data due to pressure transducer measurement had both comprised the data that backhaul also comprises stroke, as long as intercept efficient beyond the Great Wall, the change curve of cavity of resorption pressure in stroke movement, binding constant A
1, A
2, m, g, just the form of the acceleration a curve of piston movement can be showed.
Comprehensive above, by the curvilinear integral of acceleration a in the stroke stage, just the maximal rate v of piston movement can be obtained, thus obtain the maximum kinetic energy of piston movement
Analyze nitrogen chamber pressure curve, draw the cycle T=t/n of the time t that n peak value is used, piston movement, frequency is f=1/T.
The data that pressure transducer exports are by computer acquisition process, and the result available computers of output shows and prints.
Claims (3)
1. a detection method for hydraulic breaking hammer impact energy, the method comprises the following steps: 1) pressure transducer gathers pressure signal, and sends to data collecting card;
2) data collecting card is changed pressure signal, and the signal after conversion is sent to computing machine;
3) pressure signal stores in memory by computing machine, and is shown over the display in graph form by pressure signal;
It is characterized in that, described detection method is further comprising the steps of:
4) computing machine judges hydraulic hammer classification, if be judged as nitrogen explosion type hydraulic hammer, carry out step 5), if be judged as dynamic hydraulic combined formula hydraulic hammer, carry out step 6), if be judged as full-liquid type hydraulic hammer, carry out step 7);
5) computing machine is according to the physical parameter of the nitrogen pressure curve of nitrogen explosion type hydraulic hammer, epicoele oil pressure curve and nitrogen explosion type hydraulic hammer, calculates the accelerating curve of the piston of nitrogen explosion type hydraulic hammer, and carry out step 8);
6) computing machine is according to the physical parameter of the nitrogen pressure curve of dynamic hydraulic combined formula hydraulic hammer, epicoele oil pressure curve and dynamic hydraulic combined formula hydraulic hammer, calculates the accelerating curve of the piston of dynamic hydraulic combined formula hydraulic hammer, and carry out step 8);
7) the epicoele oil pressure curve of computing machine according to full-liquid type hydraulic hammer and the physical parameter of cavity of resorption oil pressure curve and full-liquid type hydraulic hammer, calculate the accelerating curve of the piston of full-liquid type hydraulic hammer, and carry out step 8);
8) utilize Simpson's rule to carry out numerical integration process to the accelerating curve of piston, draw maximal rate, and draw impact energy further;
Described step 5) comprise the nitrogen pressure curve crest of computing machine intercepting nitrogen explosion type hydraulic hammer to the data in decrease amount section, intercept the data of the epicoele oil pressure curve in same time section simultaneously;
Described step 6) comprise the nitrogen pressure curve crest of computing machine intercepting dynamic hydraulic combined formula hydraulic hammer to the data in decrease amount section, intercept the data of the epicoele oil pressure curve in same time section simultaneously;
Described step 7) comprise computing machine the value of any point on epicoele oil pressure curve and the average centered by this point in two seconds are compared, and intercept oil pressure value from being greater than average to the curve be less than average.
2. the detection method of a kind of hydraulic breaking hammer impact energy according to claim 1, it is characterized in that, described step 1) in pressure transducer be arranged on valve place and the epicoele fluid mouth of pipe place of the nitrogen chamber of nitrogen explosion type hydraulic hammer, or be arranged on the valve place of nitrogen chamber and the epicoele fluid mouth of pipe place of dynamic hydraulic combined formula hydraulic hammer, or be arranged on epicoele fluid mouth of pipe place and the cavity of resorption fluid mouth of pipe place of full-liquid type hydraulic hammer.
3. the detection method of a kind of hydraulic breaking hammer impact energy according to claim 1, it is characterized in that, described step 7) also comprise computing machine the value of any point on cavity of resorption oil pressure curve and the average centered by this point in two seconds are compared, and intercept oil pressure value from being greater than average to the curve be less than average.
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Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US5291955A (en) * | 1993-03-15 | 1994-03-08 | Clark Thomas P | Hydraulic hammer |
JP3192045B2 (en) * | 1993-12-17 | 2001-07-23 | 豊田工機株式会社 | Impact force monitoring device |
US6510902B1 (en) * | 1999-05-22 | 2003-01-28 | Krupp Berco Bautechnik Gmbh | Method and device for determining the operating time and the operating condition of a hydraulic percussion unit |
CN101189103A (en) * | 2005-06-03 | 2008-05-28 | 株式会社小松制作所 | Work machine |
Family Cites Families (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP3056039B2 (en) * | 1994-03-30 | 2000-06-26 | 日本車輌製造株式会社 | Apparatus and method for measuring impact energy |
JPH11333757A (en) * | 1998-05-22 | 1999-12-07 | Hitachi Constr Mach Co Ltd | Crusher control device of hydraulic working machine |
-
2011
- 2011-04-02 CN CN201110084152.0A patent/CN102735385B/en not_active Expired - Fee Related
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US5291955A (en) * | 1993-03-15 | 1994-03-08 | Clark Thomas P | Hydraulic hammer |
JP3192045B2 (en) * | 1993-12-17 | 2001-07-23 | 豊田工機株式会社 | Impact force monitoring device |
US6510902B1 (en) * | 1999-05-22 | 2003-01-28 | Krupp Berco Bautechnik Gmbh | Method and device for determining the operating time and the operating condition of a hydraulic percussion unit |
CN101189103A (en) * | 2005-06-03 | 2008-05-28 | 株式会社小松制作所 | Work machine |
Non-Patent Citations (3)
Title |
---|
JP特开平11-333757A 1999.12.07 * |
JP特开平7-270263A 1995.10.20 * |
JP特许第3192045号B2 2001.05.25 * |
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